MTG NEET Physics

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Two springs A (force constants ka) and B (force constants kB) are connected as shown below. Given k = kA = kB/2. what is the potential energy stored in springs A and B ?
28
Oct
Two springs A (force constants ka) and B (force constants kB) are connected as shown below. Given k = kA = kB/2. what is the potential energy stored in springs A and B ? Two springs A (force constants ka) and B (force constants kB) are connected as shown below. Given k = kA = [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: Two springs A (force constants ka) and B (force constants kB) are connected as shown below. Given k = kA = kB/2. what is the potential energy stored in springs A and B ? ,
Find the keq of the given systems. (a) 2k/3 (b) 5k/2 (c) k/2 (d) 3k/5
28
Oct
Find the keq of the given systems. (a) 2k/3 (b) 5k/2 (c) k/2 (d) 3k/5 Find the keq of the given systems. (a) 2k/3 (b) 5k/2 (c) k/2 (d) 3k/5 October 28, 2020 Category: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: Find the keq of the given systems. (a) 2k/3 (b) 5k/2 (c) k/2 (d) 3k/5 ,
A spring of length l and spring constant k is broken into two parts of equal length. They are then connected in parallel. What is the value of keq ?
28
Oct
A spring of length l and spring constant k is broken into two parts of equal length. They are then connected in parallel. What is the value of keq ? A spring of length l and spring constant k is broken into two parts of equal length. They are then connected in parallel. What is [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: A spring of length l and spring constant k is broken into two parts of equal length. They are then connected in parallel. What is the value of keq ? ,
A particle which is constrained to move along the x-axis, is subjected to a force in the same direction which varies with the distance x of the particle from the origin as F(x)=−kx+ax^3 . Here k and a are positive constants. For x ≥ 0, the functional form of the potential energy U(x) of the particle is
28
Oct
A particle which is constrained to move along the x-axis, is subjected to a force in the same direction which varies with the distance x of the particle from the origin as F(x)=−kx+ax^3 . Here k and a are positive constants. For x ≥ 0, the functional form of the potential energy U(x) of the [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: A particle which is constrained to move along the x-axis , is subjected to a force in the same direction which varies with the distance x of the particle from the origin as F(x)=−kx+ax^3 . Here k and a are positive constants. For x ≥ 0 , the functional form of the potential energy U(x) of the particle is ,
A particle is placed at the origin and a force F=Kx is acting on it (where k is a positive constant). If U(0)=0, the graph of U(x) verses x will be (where U is the potential energy function.)
28
Oct
A particle is placed at the origin and a force F=Kx is acting on it (where k is a positive constant). If U(0)=0, the graph of U(x) verses x will be (where U is the potential energy function.) A particle is placed at the origin and a force F=Kx is acting on it (where k [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: A particle is placed at the origin and a force F=Kx is acting on it (where k is a positive constant). If U(0)=0 , the graph of U(x) verses x will be (where U is the potential energy function.) ,
A particle which is constrained to move along the x-axis, is subjected to a force in the same direction which varies with the distance x of the particle from the origin as F(x)=−b/x^2 . where b is positive constants. For x ≥ 0, the functional form of the potential energy U(x) of the particle is
28
Oct
A particle which is constrained to move along the x-axis, is subjected to a force in the same direction which varies with the distance x of the particle from the origin as F(x)=−b/x^2 . where b is positive constants. For x ≥ 0, the functional form of the potential energy U(x) of the particle is [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: A particle which is constrained to move along the x-axis , is subjected to a force in the same direction which varies with the distance x of the particle from the origin as F(x)=−b/x^2 . where b is positive constants. For x ≥ 0 , the functional form of the potential energy U(x) of the particle is ,
The figure gives the potential energy function U(x) for a system in which a particle is in one-dimensional motion. In which region the magnitude of the force on the particle is greatest ?
28
Oct
The figure gives the potential energy function U(x) for a system in which a particle is in one-dimensional motion. In which region the magnitude of the force on the particle is greatest ? The figure gives the potential energy function U(x) for a system in which a particle is in one-dimensional motion. In which region [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: The figure gives the potential energy function U(x) for a system in which a particle is in one-dimensional motion. In which region the magnitude of the force on the particle is greatest ? ,
The potential energy of a certain particle is given by U= 2/1(x^2 − z^2). The force acting on the particle is.
28
Oct
The potential energy of a certain particle is given by U= 2/1(x^2 − z^2). The force acting on the particle is. The potential energy of a certain particle is given by U= 2/1(x^2 − z^2). The force acting on the particle is. October 28, 2020 Category: Chapter 6 - Work, Energy and Power , MTG [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: The potential energy of a certain particle is given by U= 2/1(x^2 − z^2). The force acting on the particle is. ,
The potential energy for a force field F is given by U(x,y) = cos(x+y). The force acting on a particle at position given by coordinates (0, π/4) is:
28
Oct
The potential energy for a force field F is given by U(x,y) = cos(x+y). The force acting on a particle at position given by coordinates (0, π/4) is: The potential energy for a force field F is given by U(x y) = cos(x+y). The force acting on a particle at position given by coordinates (0 [...]
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: The potential energy for a force field F is given by U(x , y) = cos(x+y). The force acting on a particle at position given by coordinates (0 , π/4) is: ,
The potential energy function associated with the force F = 4xyi + 2x^2j is
28
Oct
The potential energy function associated with the force F = 4xyi + 2x^2j is The potential energy function associated with the force F = 4xyi + 2x^2j is October 28, 2020 Category: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Posted in: Chapter 6 - Work, Energy and Power , MTG NEET Physics , Part 1 ,
Tags: The potential energy function associated with the force F = 4xyi + 2x^2j is ,